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Unit 8, Lesson 14

Completing the Square (Part 3)

Algebra 1

14.1

Warm-up

Standards Alignment

Building On

Addressing

Building Toward

Instructional Routines

None

Materials

None

Activity Narrative

In this Warm-up, students make a conjecture about the relationship between values from a quadratic expression in factored form to values of the same expression in standard form by using a specific example. Previously, students have seen a pattern for expressions in the form , and here they begin to generalize to a pattern for expressions in the form (MP8).

At this stage, it is not important for them to notice all of the patterns or express their conjecture in precise mathematical language. These patterns will be more closely explored later in the lesson.

Launch

Arrange students in groups of 2. Give students 3 minutes to expand the expression and notice a pattern they might be able to express as a conjecture. Students do not need to write out their conjecture, but should be able to express any patterns they notice during the Activity Synthesis.

Activity

None

Previously, we saw that can be expanded to standard form as .

Expand into standard form.
Be prepared to share a conjecture about the relationship between the coefficients 5 and 3 in the factored form and the values in standard form.

Activity Synthesis

Display the solution for the first question, then invite 1–2 students to share their conjectures. Encourage students to share even if their ideas are only partial.

It is okay if the conjectures are not complete or correct at this point. The conjectures will be tested in the following activities.

14.2

Activity

Instructional Routines

5 Practices

Materials

None

Activity Narrative

In this activity, students use the structure they saw earlier to rewrite squared expressions of the form , where is not 1, into standard form. Through repeated reasoning, students see how the coefficient is related to the values of and when the expression is expanded into , and how the is related to (MP8).

Monitor for strategies students use to rewrite the expressions from factored form to standard form. Here are some strategies students may use from less efficient to more efficient:

Drawing rectangular diagrams
Applying the distributive property, writing out all the expanded terms, and combining like terms
Generalizing that when expanding an expression such as :
- The coefficient 4 in gets squared, so in is .
- The coefficient 4 in gets multiplied by the constant term 1 twice, so is .
- The constant term 1 in is squared, so is .

Identify students using each strategy and invite them to share during the class discussion.

14.3

Activity

Instructional Routines

None

Materials

None

Activity Narrative

Earlier, students noticed that when an expression is squared and written in standard form , the value of is , and the value of is . In this activity, they use these observations to complete expressions to make them perfect squares and then write them as squared factors. Then, they apply this skill to solve quadratic equations.

14.4

Activity

Optional

Instructional Routines

MLR8: Discussion Supports Take Turns

Materials

None

Activity Narrative

This activity is optional. It shows three different methods for solving an equation: by rewriting it in factored form, by transforming it into an expression in which the squared term has a coefficient 1 and then rewriting in factored form, and by completing the square. The second method involves temporarily substituting a part of the expression with another variable so that the squared term has a coefficient of 1, which makes it easier to rewrite in factored form. Students encountered this strategy in an optional activity (“Making It Simpler”) in an earlier lesson. If students did not do that optional activity, consider doing it before using this activity.

The numbers in the equations here do not lend themselves to be easily rewritten in factored form (without guessing and checking or substitution) or as perfect squares (because the leading coefficients and the constant terms are not perfect squares), but students see that these equations can be solved with these strategies. The activity further illustrates that any of these methods can be rather tedious, providing further motivation to solve using the quadratic formula, which students will learn in a future lesson.

Lesson Synthesis

Invite students to reflect on the process of completing the square for various kinds of equations. Display equations such as the following, and ask students which ones would be fairly easy to solve by completing the square, which ones would not be, and why.

Discuss questions such as:

“What number would you add to (the third equation on the list) to make it a perfect square? How do you know?” (64. The coefficient 32 is equal to , so is 8. The number to be added is , which is 64.)
“What about ? How do you know?” (1. The coefficient 6 is equal to , so is 1. The number to be added is , which is 1.)
“Do certain features or numbers in an equation make it easier or harder to solve it by completing the square? If so, which features or what kinds of numbers?” (It’s easier when the coefficient of the squared term is 1 or another perfect square. It’s harder when some of the coefficients are fractions or the quadratic term’s coefficient is not a perfect square.)

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Student Lesson Summary

In earlier lessons, we worked with perfect squares such as and . We learned that their equivalent expressions in standard form follow a predictable pattern:

In general, can be written as .
If a quadratic expression of the form is a perfect square, and the value of is 1, then the value of is , and the value of is for some value of .

In this lesson, the variables in the factors being squared had coefficients other than 1, for example and . Their equivalent expressions in standard form also followed the same pattern we saw earlier.

squared factor	standard form

In general, can be written as:

If a quadratic expression is of the form , then:

The value of is .
The value of is .
The value of is .

We can use this pattern to help us complete the square and solve equations when the squared term has a coefficient other than 1—for example, .

What constant term can we add to make the expression on the left of the equal sign a perfect square? And how do we write this expression as a squared factor?

, which is , so , and the squared factor could be .
40 is equal to , so , or . This means that .
If is , then , or .
So the expression is a perfect square and is equivalent to .

Let’s solve the equation by completing the square!

Activity Synthesis

The purpose of the discussion is to express a general pattern for the connection between an expression of the form and the same expression in standard form.

Invite previously selected groups to share their strategies for rewriting the expressions. Sequence the discussion of the strategies in the order listed in the Activity Narrative. If possible, record and display their work for all to see.

Display the general form of a quadratic expression in standard form, , and the general form of a quadratic expression from this activity in factored form, .

Connect the different responses to the learning goals by asking questions such as:

“What is the relationship between in standard form and and from the factored form? How can we see it in each expansion strategy?” (. It is in the top left box of the diagram, the product of with itself in the distribution method, and part of the pattern in problems of this type.)
“What is the relationship between in standard form and and from the factored form? How can we see it in each expansion strategy?” (. It is the sum of the top right and bottom left boxes in the diagram. When using the distributive property, the product of and appears twice, so the sum is .)
“What is the relationship between in standard form and and from the factored form? How can we see it in each expansion strategy?” (. It is in the bottom right box of the diagram, the product of with itself in the distribution method, and part of the pattern in problems of this type.)

Revisit the conjectures made during the Warm-up briefly to address whether they are supported by these patterns.

Then, discuss how students used their insights from the first question to help them identify perfect squares, or turn expressions into perfect squares, in the second question. Make sure students see the structure behind the values of , , and when the expression is a perfect square. This structure will help them complete the square in the next activity.

Launch

To reiterate the connections between and its equivalent expression of the form , display these two expressions for all to see, and ask students:

“If the two expressions are perfect squares and are equivalent, how is related to ?” ( is .)
“How is related to ?” ( is .)
“How is related to and ?” ( is .)

Tell students they will use these insights to complete some squares. Consider keeping students in groups of 2.

Representation: Internalize Comprehension. Use color coding and annotations to highlight connections between representations in a problem. For example, color code the connections between and .
Supports accessibility for: Visual-Spatial Processing

Activity

None

Find the value of to make each expression in the left column a perfect square in standard form. Then, write an equivalent expression in the form of squared factor. In the last row, write your own pair of equivalent expressions.

standard form	squared factor

Solve each equation by completing the square:

Student Response

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Building on Student Thinking

If students struggle to follow the generalized relationships between and its equivalent expression of the form (as discussed in the Launch), consider revisiting a concrete example from an earlier activity—for example, . Ask students to relate each term in the squared factor to the terms of its expression in standard form, .

If students get stuck finding the constant, have them write something like , then expand the right side and compare the expanded form to the left side of the equation to help them move forward.

Launch

Display the perfect squares students saw in an earlier activity. Ask them what they notice about the coefficient of the square term in each expression.

Students are likely to notice that the coefficient of every is a perfect square, which makes it easier to rewrite the completed square as a squared factor. Solicit some ideas about whether we could still complete the square if a quadratic expression does not have a perfect square for the coefficient of . Then, tell students that they will explore a few methods for solving such equations.

Arrange students in groups of 2. Ask one partner to study the first two methods and the other partner to study the third method, and then ask both partners to take turns explaining their understanding to each other. Discuss the methods, especially the third one, before students begin using them to solve equations.

Make sure students see that, in both the second and third methods, the first step involves multiplying both sides of the equation by 3 to make the coefficient of a perfect square. Each term on the left side of the equation changes by a factor of 3, but the right side of the equation remains 0 because multiplying 0 by any number results in 0.

If time is limited, consider asking students to solve only three equations, using each method once.

Action and Expression: Internalize Executive Functions. To support development of organizational skills in problem-solving, chunk this task into more manageable parts. For example, cut the three methods into separate pieces. Begin by presenting one method at a time, and invite students to annotate the examples as they analyze the steps. After students annotate the first method, invite students who have great clarity in their annotations to share their work, and display for all to see. Encourage students to refer to their annotations as they approach the last problems themselves.
Supports accessibility for: Organization, Attention

Activity

None

Here are three methods for solving .

Try to make sense of each method.

Method 1:

Method 2:

Method 3:

Once you understand the methods, use each method at least one time to solve these equations.

Student Response

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Lesson 14

Completing the Square (Part 3)

Warm-up

Standards Alignment

Building On

Addressing

Building Toward

HSA-SSE.A.2

Instructional Routines

Materials

Activity Narrative

Launch

Activity

Activity Synthesis

Activity

Instructional Routines

Materials

Activity Narrative

Activity

Instructional Routines

Materials

Activity Narrative

Activity

Instructional Routines

Materials

Activity Narrative

Lesson Synthesis

Student Lesson Summary

Student Response

Building on Student Thinking

Launch

Activity

Student Response

Building on Student Thinking

Activity Synthesis

Launch

Activity

Student Response

Building on Student Thinking

Activity Synthesis

Launch

Activity

Student Response

Building on Student Thinking

Activity Synthesis

Standards Alignment

Building On

Addressing

HSA-SSE.A.2

Building Toward

HSA-REI.B.4.a

Standards Alignment

Building On

Addressing

HSA-REI.B.4.b

HSA-SSE.A.2

Building Toward

Standards Alignment

Building On

Addressing

HSA-REI.B.4.a

HSA-REI.B.4.b

Building Toward

HSA-REI.B.4.b